test structure and probe for differential signals

ABSTRACT

A test structure including a differential gain cell and a differential signal probe include compensation for the Miller effect reducing the frequency dependent variability of the input impedance of the test structure.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 12/157,658, filed Jun. 11, 2008, which is a continuation of U.S. patent application Ser. No. 11/710,149, filed Feb. 22, 2007, which claims the benefit of U.S. Provisional App. No. 60/813,120, filed Jun. 12, 2006.

BACKGROUND OF THE INVENTION

The present invention relates to wafer probing and, more particularly, to probes and test structures for wafer probing with differential signals.

Integrated circuits (ICs) are economically attractive because large numbers of often complex circuits, for example microprocessors, can be inexpensively fabricated on the surface of a wafer or substrate. Following fabrication, individual dies, including one or more circuits, are separated or singulated and encased in a package that provides for electrical connections between the exterior of the package and the circuit on the enclosed die. The separation and packaging of a die comprises a significant portion of the cost of manufacturing the integrated circuit device and to monitor and control the IC fabrication process and avoid the cost of packaging defective dies, manufacturers commonly add electrical circuits or test structures to the wafer to enable on-wafer testing or “probing” to verify the characteristics of the integrated circuits before the dies are singulated.

A test structure typically includes a device-under-test (DUT), a plurality of metallic probe or bond pads that are deposited at the wafer's surface and a plurality of conductive vias that connect the bond pads to the DUT which is typically fabricated beneath the surface of the wafer. The DUT typically comprises a simple circuit that includes a copy of one or more of the basic elements of the integrated circuit, such as a single line of conducting material, a chain of vias or a single transistor. The circuit elements of the DUT are typically produced with the same process and in the same layers of the die as the corresponding elements of the integrated circuit. The ICs are typically characterized “on-wafer” by applying a test instrument generated signal to the test structure and measuring the response of the test structure to the signal. Since the circuit elements of the DUT are fabricated with the same process as the corresponding elements of the integrated circuit, the electrical properties of the DUT are expected to be representative of the electrical properties of the corresponding components of the integrated circuit.

At higher frequencies, on-wafer characterization is commonly performed with a network analyzer. The network analyzer comprises a source of an AC signal, commonly, a radio frequency (RF) signal, that is used to stimulate the DUT of a test structure. A forward-reverse switch directs the stimulating signals to one or more of the bond pads of the test structure. Directional couplers or bridges pick off the forward or reverse waves traveling to or from the test structure. These signals are down-converted by intermediate frequency (IF) sections of the network analyzer where the signals are filtered, amplified and digitized for further processing and display. The result is a plurality of s-parameters (scattering parameters), the ratio of a normalized power wave comprising the response of the DUT to a normalized power wave comprising the stimulus supplied by the signal source.

The preferred interconnection for communicating the signals between the signal source and the receiver of the network analyzer and the test structure is coaxial cable. The transition between the coaxial cable and the bond pads of the test structure is preferably provided by a movable probe having one or more conductive probe tips that are arranged to be co-locatable with the bond pads of the test structure. The network analyzer and the test structure can be temporarily interconnected by bringing the probe tips into contact with the bond pads of the test structure.

Integrated circuits typically comprise a ground plane at the lower surface of the substrate on which the active and passive devices of the circuit are fabricated. The terminals of transistors fabricated on a semi-conductive substrate are typically capacitively interconnected, through the substrate, to the ground plane. The impedance of this parasitic capacitive interconnection is frequency dependent and at higher frequencies the ground potential and the true nature of ground referenced (single ended) signals becomes uncertain.

Balanced devices are more tolerant to poor radio frequency (RF) grounding than single ended devices making them attractive for high performance ICs. Referring to FIG. 1, a differential gain cell 20 is a balanced device comprising two nominally identical circuit halves 20A, 20B. When biased, with a DC current source 22, and stimulated with a differential mode signal, comprising even and odd mode components of equal amplitude and opposite phase (S_(i) ⁺¹ and S_(i) ⁻¹) 24, 26, a virtual ground is established at the symmetrical axis 28 of the two circuit halves. At the virtual ground, the potential at the operating frequency does not change with time regardless of the amplitude of the stimulating signal. The quality of the virtual ground of a balanced device is independent of the physical ground path and, therefore, balanced or differential circuits can tolerate poor RF grounding better than circuits operated with single ended signals. The two waveforms of the differential output signal (So⁺¹ and So⁻¹) 30, 32 are mutual references providing greater certainty in determining the transition from one binary value to the other and permitting a reduction the voltage swing of the signal and faster transition between binary values. Typically, differential devices can operate at lower signal power and higher data rates than single ended devices. In addition, noise from external sources, such as adjacent conductors, tends to couple, electrically and electromagnetically, in the common mode and cancel in the differential mode. As a result, balanced or differential circuits have good immunity to noise including noise at even-harmonic frequencies since signals that are of opposite phase at the fundamental frequency are in phase at the even harmonics. Improved tolerance to poor RF grounding, increased resistance to noise and reduced signal power make differential devices attractive for operation at higher frequencies.

A DUT comprising a differential gain cell provides a basis for a test structure enabling high frequency, on-wafer evaluation of devices included in the marketable integrated circuits fabricated on the wafer. However, the impedance of the internal connections of the DUT's components are often frequency dependant complicating de-embedding of the DUT and affecting the accuracy of the testing. For example, the input and output of a differential gain cell, such as the differential gain cell 20, are commonly capacitively interconnected as a result of parasitic capacitance connecting the terminals of the cell's transistors. Parasitic capacitance 42 between the gate 38, 40 and the drain 34, 36, a result of diffusion of the drain dopant under the oxide of the gate, is intrinsic and typical of MOS transistors. As a result to the transistor's gain, a change in the gate voltage produces an even larger change in the voltage at the transistor's drain. The application of differing voltages at the terminals of the parasitic gate-to-drain capacitor (C_(gd)) causes the capacitor to behave as a much larger capacitance, a phenomenon known as the Miller effect. As a result, input impedance of the differential device varies substantially with frequency, producing instability in the operation of the differential device.

What is desired is a method and apparatus for testing a differential device that minimizes or eliminates the Miller effect.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is schematic diagram of a balanced device.

FIG. 2 is a schematic illustration of a probe and a differential test structure comprising field effect transistors and a pair of Miller effect neutralizing capacitors.

FIG. 3 is a schematic illustration of a probe and a differential test structure comprising bipolar junction (BJT) transistors and a pair of Miller effect neutralizing capacitors.

FIG. 4 is a perspective view of a test structure and a probe.

FIG. 5 is a schematic illustration of a differential test structure for go-no go testing of the functionality of a transistor.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Referring in detail to the drawings where similar parts are identified by like reference numerals, and, more particularly to FIG. 1, a differential gain cell 20 is a balanced device comprising two nominally identical circuit halves 20A, 20B. When biased, with a DC current source 22, and stimulated with a differential mode signal, comprising even and odd mode components of equal amplitude and opposite phase (S_(i) ⁺¹ and S_(i) ⁻¹) 24, 26, a virtual ground is established at the symmetrical axis 28 of the two circuit halves. At the virtual ground, the potential at the operating frequency does not change with time regardless of the amplitude of the stimulating signal. The quality of the virtual ground of a balanced device is independent of the physical ground path and, therefore, balanced or differential circuits can tolerate poor RF grounding better than circuits operated with single ended (ground referenced) signals. Differential devices can also typically operate with lower signal power and at higher data rates than single ended devices and have good immunity to noise from external sources, such as adjacent conductors, including noise at even-harmonic frequencies.

However, the response of integrated circuits, including test structures comprising differential gain cells, to high frequency signals is typically frequency dependent. Integrated circuits are fabricated by depositing layers of semi-conductive and insulating materials on a semi-conductive substrate and intrinsic frequency dependent connections commonly exist between the various elements of the fabricated devices. One such intrinsic frequency dependent connection connects the gates and drains of MOS transistors and the bases and collectors of bipolar junction (BJT) transistors. For example, an intrinsic parasitic capacitance (C_(gd)) interconnects the gate and the drain of a typical MOS transistor because the drain dopant diffuses under the oxide comprising the transistor's gate. As the frequency of the stimulating signal increases, the impedance between gate and drain of the transistor and, therefore, the input impedance of the differential gain cell changes. Moreover, due to the gain of the transistor, any change in voltage at the gate of the transistor is amplified at the drain of the transistor causing the parasitic capacitance (C_(gd)) to appear to be a much larger capacitor; a phenomenon known as the Miller effect. The inventors realized that the signals conducted by the respective transistors of the differential gain cell are mirror images and concluded that the Miller effect could be minimized or eliminated and the input impedance of a test structure comprising a differential gain cell stabilized connecting the gate of one transistor to the drain of the second transistor with a capacitor having a value equal to the parasitic gate-to-drain capacitance (C_(gd)).

Referring to FIG. 2, a test structure 50 comprises a differential gain cell 51 including transistors 52A, 52B. The gates of the respective transistors are connected to probe pads 54, 56 Probe tips 64, 66 arranged to be co-locatable with the probe pads are connected to a source 74 of a differential input signal comprising the component signal, S₁ ⁺¹′ and its differential complement signal, The source of the differential signal is typically a radio frequency (RF) source included in a network analyzer 76. The network analyzer also includes a sink 78 for the output signal of the test structure comprising components S_(o) ⁺¹ and S_(o) ⁻¹. The respective components of the output signal are transmitted from the drains of the transistors to probe pads 58, 60 which are connectible to the signal sink through probe tips 68, 70. The sources of the transistors are interconnected and connected to a bias probe pad 62 which is engageable with a probe tip 72. The probe tip is interconnected to a DC current source 80 that provides the bias for the differential gain cell.

Intrinsic in each transistor 52A, 52B is parasitic capacitance (C_(gd)) 82A, 82B interconnecting the respective gates and drains which comprise respectively the input terminals and the output terminals of the test structure. As a result of the gain (A) of the transistor, a change in voltage (dV) at the gate of a transistor is amplified at the drain (A*dV) causing the opposing sides of the parasitic capacitance to experience differing voltage. As a result of a phenomenon known as the Miller effect, the parasitic capacitance (C_(gd)) has the effect of a larger capacitor causing the input impedance of the test structure to vary substantially with frequency. To reduce or eliminate the effect of the parasitic gate-to-drain capacitance and provide a more constant input impedance for the test structure, a compensating capacitor 84A, 84B is connected from the gate of each transistor, for example the gate of transistor 52A, to the drain of the second transistor of the differential gain cell, for example the drain of transistor 52B. The compensating capacitor has a value equal to the value of C_(gd). Since the transistors of the differential gain cell are matched and the phase of the differential input signal component S_(i) ⁺¹ is 180° from the phase of the differential output signal component S_(o) ⁻¹, the change in voltage at the drain of a transistor due to the gate-to-drain capacitance, for example, A*dV, is offset by the voltage at the compensating capacitor #(−A*dV) and the input impedance of the test structure remains constant.

Referring to FIG. 3, another exemplary embodiment of a test structure 100 comprises a differential gain cell 102 comprising bipolar junction (BJT) transistors 104A, 104B connected in a common emitter configuration. The bases of the transistors are connected to probe pads 106, 108 that are engageable by probe tips 106, 108 interconnected to a source 126 of a differential signal comprising the component input signals (S_(i) ⁺¹ and S_(i) ⁻¹). The collectors of the transistors are connected to probe pads 110, 112 which are engageable by probe tips 120, 122 which are interconnected to a sink 128 for the output signal of the differential cell comprising the component signals (S_(o) ⁺¹ and S_(o) ⁻¹). The emitters of the matched transistors are interconnected and connected through a probe tip 124, contactable with a bias probe pad 114, to a DC current source 130 that biases the differential gain cell. Each BJT includes parasitic base-to-collector capacitance (C_(bc)) 132 that comprises a frequency dependent interconnection between an input and an output of the test structure. To counter the Miller effect, a compensating capacitor 134 having a value equal to C_(bc) interconnects the gate of each of the transistors 104A, 104B respectively to the collector of the other transistor of the differential gain cell.

The compensating capacitors may be fabricated on the wafer as part of the test structure enabling consistent matching to the parasitic capacitance of the transistors. On the other hand, the compensating capacitors may be connected across the respective probe tips arranged to engage the appropriate probe pads. Typically, differential probing is performed with two probes. Referring to FIG. 4, the differential test structure 200 comprises at least four bond or probe pads, including probe pads 202, 204 for the input signal components and probe pads 206, 208 for the output signal components that are arranged in a linear array and connected to the DUT 212, which is fabricated below the surface of a wafer 214, by a plurality of conductive vias 216. The fifth probe pad 210, through which the DUT is biased, is preferably fabricated within the linear array but could be offset. Arrangement of the probe pads in a linear array enables fabrication of the test structure in a saw street 218 (indicated by bracket) between dies 220 permitting a reduction in the area of the wafer that is occupied by test structures which serve no purpose after the dies are singulated. The linear arrangement of probe pads also enables probing with a single probe comprising a linear array of at least four probe tips 222, 224, 226, 228 which may be fabricated on the surfaces of a dielectric plate 232 and which are arranged to be co-locatable with the probe pads for the input and output signals. The fifth probe tip 230, through which the DUT is biased, is preferably fabricated in the linear array probe tips but could be offset or arranged at a different angle to the wafer. The linear arrangement of probe tips facilitates fabrication of conductors 234 and compensating capacitors 236 interconnecting the probe tips 222, 224 transmitting the input signals and the probe tips 226, 228 transmitting the output signals for the two transistors of the differential gain cell of the DUT.

During the fabrication of integrated circuits (ICs) it is desirable to be able to easily determine if transistors included in the integrated circuits are functional. Referring to FIG. 4, an easily tested go-no go test structure 150 comprising a differential gain cell 152 having circuit elements fabricated with the same process and in the same layers of the wafer as their counterpart elements of the marketable integrated circuits. The test structure comprises compensating capacitors 156 connecting the gate of each transistor 154A, 1548 to the drain of its counterpart, respectively 1548, 154A, to neutralize the Miller effect originating with the parasitic gate-to-drain capacitance (C_(gd)) and stabilize the input impedance of the test structure. A resistor network comprising resistors 178 connect the signal input probe tips 168, 170, arranged to engage the input probe pads 158, 160, and the signal source 74. Likewise, the signal output probe pads 162, 164 are connected to the signal sink 78 through probe tips 172, 174 and resistors 182, 184. The test structure is biased through the probe pad 166 and the probe tip 176 which is connected to ground through the bias resistor 186. The resistors at all terminations stabilize the DC operation of the amplifier and prevent it from oscillating by reducing the Q factor of resonances produced by the capacitive and inductive interconnections of the device parasitics. The values of the resistors are selected to provide stability and a convenient level of gain, preferably, approximately unity. Data is collected by testing a plurality transistor pairs known to be good. Comparing this data to data obtained by testing on-wafer test structures provides a go-no go gauge of transistor functionality that can be easily used during the production process.

The input impedance of a test structure comprising a differential gain cell is stabilized by interconnecting the gate of one transistor and the drain of the second transistor of the differential pair with a capacitor having a value approximating the parasitic gate-to-drain (base-to-collector) capacitance of the device.

The detailed description, above, sets forth numerous specific details to provide a thorough understanding of the present invention. However, those skilled in the art will appreciate that the present invention may be practiced without these specific details. In other instances, well known methods, procedures, components, and circuitry have not been described in detail to avoid obscuring the present invention.

All the references cited herein are incorporated by reference.

The terms and expressions that have been employed in the foregoing specification are used as terms of description and not of limitation, and there is no intention, in the use of such terms and expressions, of excluding equivalents of the features shown and described or portions thereof, it being recognized that the scope of the invention is defined and limited only by the claims that follow. 

1. A test structure comprising a cell including a first input signal probe pad capacitively interconnected to a first output signal probe pad and a second input signal probe pad capacitively interconnected to a second output signal probe pad, said test structure comprising: (a) a first capacitor interconnecting said first input signal probe pad and said second output signal probe pad; and (b) a second capacitor interconnecting said second input signal probe pad and said first output signal probe pad, wherein said first capacitor has a capacitance related to a capacitance of said interconnection of said first input signal probe pad and said first output signal probe pad and said second capacitor has a capacitance related to a capacitance of said interconnection of said second input signal probe pad and said second output signal probe pad.
 2. The test structure of claim 1 wherein said first capacitor has a capacitance substantially equal to a capacitance of said interconnection of said first input signal probe pad and said first output signal probe pad and said second capacitor has a capacitance substantially equal to a capacitance of said interconnection of said second input signal probe pad and said second output signal probe pad.
 3. A probe for probing a cell comprising a first input signal probe pad capacitively interconnected to a first output signal probe pad and a second input signal probe pad capacitively interconnect to a second output signal probe pad, said probe comprising: (a) a first probe tip connectible to a source of a first input signal and arranged for contact with said first input signal probe pad of said cell; (b) a second probe tip connectible to a source of a second input signal and arranged for contact with said second input signal probe pad; (c) a third probe tip connectible to a sink of a first output signal and arranged for contact with said first output signal probe pad; (d) a fourth probe tip connectible to a sink of a second output signal and arranged to contact said second output signal probe pad; (e) a first capacitive structure interconnecting said first probe tip and said fourth probe tip; and (f) a second capacitive structure interconnecting said second probe tip and said third probe tip.
 4. The probe of claim 3 wherein said first, said second, said third and said fourth probe tips are arranged in a linear array.
 5. The probe of claim 3 wherein said capacitive structure interconnecting said first probe tip and said fourth probe tip has a capacitance substantially equal to a capacitance of said interconnection of said first input signal probe pad and said first output signal probe pad and said capacitive structure interconnecting said second probe tip and said third probe tip has a capacitance substantially equal to a capacitance of said interconnection of said second input signal probe pad and said second output signal probe pad.
 6. The probe of claim 5 wherein said first, said second, said third and said fourth probe tips are arranged in a linear array.
 7. A method for probing a cell comprising a first input signal probe pad capacitively interconnected to a first output signal probe pad and a second input signal probe pad capacitively interconnected to a second output signal probe pad, said method comprising steps of: (a) interconnecting said first input signal probe pad and said second output signal probe pad with a capacitor approximately equaling a capacitance of said interconnection of said first input signal probe pad and said first output signal probe pad; and (b) interconnecting said second input signal probe pad and said first output probe pad with a capacitor approximately equaling a capacitance of said interconnection of said second input signal probe pad and said second output signal probe pad.
 8. A test structure for testing a functionality of a transistor, said test structure comprising: (a) a first transistor including: (i) a first terminal connectible through a first resistance to a source of a first component of a signal; (ii) a second terminal connectible through a second resistance to a sink for a first component of an output signal and interconnected to said first terminal by a parasitic capacitance; and (iii) a third terminal; (b) a second transistor including: (i) a first terminal connectible through a third resistance to a source of a second component of a signal; (ii) a second terminal connectible through a fourth resistance to a sink for a second component of an output signal and interconnected to said first terminal by a parasitic capacitance; and (iii) a third terminal interconnected with said third terminal of said first transistor and a source of a bias voltage; (c) a first compensating capacitive structure connecting said first terminal of said first transistor to said second terminal of said second transistor; and (d) a second compensating capacitive structure connecting said first terminal of said second transistor to said second terminal of said first transistor.
 9. The test structure of claim 8 wherein said first compensating capacitive structure has a capacitance substantially equal to said parasitic capacitance interconnecting said first terminal of said first transistor and said second terminal of said first transistor and said second compensating capacitive structure has a capacitance substantially equal to said parasitic capacitance interconnecting said first terminal of said second transistor to said second terminal of said second transistor.
 10. The test structure of claim 8 wherein said first, said second, said third and said fourth resistances have values selected to cause said test structure to have a gain approximating unity. 